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Inside the hunt for new physics at the world’s largest particle collider

Diane Davis

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Not everyone is fully on board. Some theorists worry that the approach will only yield more false alarms from the collider—more tentative blips in the data like “two-sigma bumps,” so named for their low level of statistical certainty. These are generally flukes that eventually disappear with more data and analysis. Koren is concerned that this will be even more the case with such an open-ended technique: “It seems they want to have a machine that finds more two-sigma bumps at the LHC.” 

Nachman told me that he received a lot of pushback; he says one senior physicist told him, “If you don’t have a particular model in mind, you’re not doing physics.” Searches based on specific models, he says, have been amazingly productive—he points to the discovery of the Higgs boson as a prime example—but they don’t have to be the end of the story. “Let the data speak for themselves,” he says.

Building bigger machines

One thing particle physicists would really like in the future is more precision. The problem with protons is that each one is actually a bundle of quarks. Smashing them together is like a subatomic food fight. Ramming indivisible particles like electrons (and their antiparticles, positrons) into one another results in much cleaner collisions, like the ones that take place on a pool table. Without the mess, researchers can make far more precise measurements of particles like the Higgs. 

An electron-positron collider would produce so many Higgs bosons so cleanly that it’s often referred to as a “Higgs factory.” But there are currently no electron-­positron colliders that have anywhere near the energies needed to probe the Higgs. One possibility on the horizon is the Future Circular Collider (FCC). It would require digging an underground ring with a circumference of 55 miles (90 kilometers)—three times the size of the LHC—in Switzerland. That work would likely cost tens of billions of dollars, and the collider would not turn on until nearly 2050. There are two other proposals for nearer-term electron-positron colliders in China and Japan, but geopolitics and budgetary issues, respectively, make them less appealing prospects. 

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A snapshot of simulated particle tracks inside a muon collider. The simulation suggests it’s possible to reconstruct information about the Higgs boson from the bottom quarks (red dots) it decays into, despite the noisy environment.

D. LUCCHESI ET AL.

Physicists would also like to go to higher energies. “The strategy has literally never failed us,” Homiller says. “Every time we’ve gone to higher energy, we’ve discovered some new layer of nature.” It will be nearly impossible to do so with electrons; because they have such a low mass, they radiate away about a trillion times more energy than protons every time they loop around a collider. But under CERN’s plan, the FCC tunnel could be repurposed to collide protons at energies eight times what’s possible in the LHC—about 50 years from now. “It’s completely scientifically sound and great,” Homiller says. “I think that CERN should do it.” 

Could we get to higher energies faster? In December, the alliteratively named Particle Physics Project Prioritization Panel (P5) put forward a vision for the near future of the field. In addition to addressing urgent priorities like continued funding for the HL-LHC upgrade and plans for telescopes to study the cosmos, P5 also recommended pursuing a “muon shot”—an ambitious plan to develop technology to collide muons. 

The idea of a muon collider has tantalized physicists because of its potential to combine both high energies and—since the particles are indivisible—clean collisions. It seemed well out of reach until recently; muons decay in just 2.2 microseconds, which makes them extremely hard to work with. Over the past decade, however, researchers have made strides, showing that, among other things, it should be possible to manage the roiling cloud of energy caused by decaying muons as they’re accelerated around the machine. Advocates of a muon collider also tout its smaller size (10 miles), its faster timeline (optimistically, as early as 2045), and the possibility of a US site (specifically, Fermi National Laboratory, about 50 miles west of Chicago).

There are plenty of caveats: a muon collider still faces serious technical, financial, and political hurdles—and even if it is built, there is no guarantee it will discover hidden particles. But especially for younger physicists, the panel’s endorsement of muon collider R&D is more than just a policy recommendation; it is a bet on their future. “This is exactly what we were hoping for,” Homiller says. “This opens a pathway to having this exciting, totally different frontier of particle physics in the US.” It’s a frontier he and others are keen to explore. 

Dan Garisto is a freelance physics journalist based in New York City.

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LLMs become more covertly racist with human intervention

Diane Davis

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LLMs become more covertly racist with human intervention

Even when the two sentences had the same meaning, the models were more likely to apply adjectives like “dirty,” “lazy,” and “stupid” to speakers of AAE than speakers of Standard American English (SAE). The models associated speakers of AAE with less prestigious jobs (or didn’t associate them with having a job at all), and when asked to pass judgment on a hypothetical criminal defendant, they were more likely to recommend the death penalty. 

An even more notable finding may be a flaw the study pinpoints in the ways that researchers try to solve such biases. 

To purge models of hateful views, companies like OpenAI, Meta, and Google use feedback training, in which human workers manually adjust the way the model responds to certain prompts. This process, often called “alignment,” aims to recalibrate the millions of connections in the neural network and get the model to conform better with desired values. 

The method works well to combat overt stereotypes, and leading companies have employed it for nearly a decade. If users prompted GPT-2, for example, to name stereotypes about Black people, it was likely to list “suspicious,” “radical,” and “aggressive,” but GPT-4 no longer responds with those associations, according to the paper.

However the method fails on the covert stereotypes that researchers elicited when using African-American English in their study, which was published on arXiv and has not been peer reviewed. That’s partially because companies have been less aware of dialect prejudice as an issue, they say. It’s also easier to coach a model not to respond to overtly racist questions than it is to coach it not to respond negatively to an entire dialect.

“Feedback training teaches models to consider their racism,” says Valentin Hofmann, a researcher at the Allen Institute for AI and a coauthor on the paper. “But dialect prejudice opens a deeper level.”

Avijit Ghosh, an ethics researcher at Hugging Face who was not involved in the research, says the finding calls into question the approach companies are taking to solve bias.

“This alignment—where the model refuses to spew racist outputs—is nothing but a flimsy filter that can be easily broken,” he says. 

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I used generative AI to turn my story into a comic—and you can too

Diane Davis

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I used generative AI to turn my story into a comic—and you can too

The narrator sits on the floor and eats breakfast with the cats. 

LORE MACHINE / WILL DOUGLAS HEAVEN

After more than a year in development, Lore Machine is now available to the public for the first time. For $10 a month, you can upload 100,000 words of text (up to 30,000 words at a time) and generate 80 images for short stories, scripts, podcast transcripts, and more. There are price points for power users too, including an enterprise plan costing $160 a month that covers 2.24 million words and 1,792 images. The illustrations come in a range of preset styles, from manga to watercolor to pulp ’80s TV show.

Zac Ryder, founder of creative agency Modern Arts, has been using an early-access version of the tool since Lore Machine founder Thobey Campion first showed him what it could do. Ryder sent over a script for a short film, and Campion used Lore Machine to turn it into a 16-page graphic novel overnight.

“I remember Thobey sharing his screen. All of us were just completely floored,” says Ryder. “It wasn’t so much the image generation aspect of it. It was the level of the storytelling. From the flow of the narrative to the emotion of the characters, it was spot on right out of the gate.”

Modern Arts is now using Lore Machine to develop a fictional universe for a manga series based on text written by the creator of Netflix’s Love, Death & Robots.

The narrator encounters the man in the corner shop who jokes about the cat food. 

LORE MACHINE / WILL DOUGLAS HEAVEN

Under the hood, Lore Machine is built from familiar parts. A large language model scans your text, identifying descriptions of people and places as well as its overall sentiment. A version of Stable Diffusion generates the images. What sets it apart is how easy it is to use. Between uploading my story and downloading its storyboard, I clicked maybe half a dozen times.

That makes it one of a new wave of user-friendly tools that hide the stunning power of generative models behind a one-click web interface. “It’s a lot of work to stay current with new AI tools, and the interface and workflow for each tool is different,” says Ben Palmer, CEO of the New Computer Corporation, a content creation firm. “Using a mega-tool with one consistent UI is very compelling. I feel like this is where the industry will land.”

Look! No prompts

Campion set up the company behind Lore Machine two years ago to work on a blockchain version of Wikipedia. But when he saw how people took to generative models, he switched direction. Campion used the free-to-use text-to-image model Midjourney to make a comic-book version of Samuel Taylor Coleridge’s The Rime of the Ancient Mariner. It went viral, he says, but it was no fun to make.

Marta confronts the narrator about their new diet and offers to cook for them. 

LORE MACHINE / WILL DOUGLAS HEAVEN

“My wife hated that project,” he says. “I was up to four in the morning, every night, just hammering away, trying to get these images right.” The problem was that text-to-image models like Midjourney generate images one by one. That makes it hard to maintain consistency between different images of the same characters. Even locking in a specific style across multiple images can be hard. “I ended up veering toward a trippier, abstract expression,” says Campion.

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The robots are coming. And that’s a good thing.

Diane Davis

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The robots are coming. And that’s a good thing.

What if we could throw our sight, hearing, touch, and even sense of smell to distant locales and experience these places in a more visceral way?

So we wondered what would happen if we were to tap into the worldwide community of gamers and use their skills in new ways. With a robot working inside the deep freezer room, or in a standard manufacturing or warehouse facility, remote operators could remain on call, waiting for it to ask for assistance if it made an error, got stuck, or otherwise found itself incapable of completing a task. A remote operator would enter a virtual control room that re-created the robot’s surroundings and predicament. This person would see the world through the robot’s eyes, effectively slipping into its body in that distant cold storage facility without being personally exposed to the frigid temperatures. Then the operator would intuitively guide the robot and help it complete the assigned task.

To validate our concept, we developed a system that allows people to remotely see the world through the eyes of a robot and perform a relatively simple task; then we tested it on people who weren’t exactly skilled gamers. In the lab, we set up a robot with manipulators, a stapler, wire, and a frame. The goal was to get the robot to staple wire to the frame. We used a humanoid, ambidextrous robot called Baxter, plus the Oculus VR system. Then we created an intermediate virtual room to put the human and the robot in the same system of coordinates—a shared simulated space. This let the human see the world from the point of view of the robot and control it naturally, using body motions. We demoed this system during a meeting in Washington, DC, where many participants—including some who’d never played a video game—were able to don the headset, see the virtual space, and control our Boston-based robot intuitively from 500 miles away to complete the task.


The best-known and perhaps most compelling examples of remote teleoperation and extended reach are the robots NASA has sent to Mars in the last few decades. My PhD student Marsette “Marty” Vona helped develop much of the software that made it easy for people on Earth to interact with these robots tens of millions of miles away. These intelligent machines are a perfect example of how robots and humans can work together to achieve the extraordinary. Machines are better at operating in inhospitable environments like Mars. Humans are better at higher-level decision-making. So we send increasingly advanced robots to Mars, and people like Marty build increasingly advanced software to help other scientists see and even feel the faraway planet through the eyes, tools, and sensors of the robots. Then human scientists ingest and analyze the gathered data and make critical creative decisions about what the rovers should explore next. The robots all but situate the scientists on Martian soil. They are not taking the place of actual human explorers; they’re doing reconnaissance work to clear a path for a human mission to Mars. Once our astronauts venture to the Red Planet, they will have a level of familiarity and expertise that would not be possible without the rover missions.

Robots can allow us to extend our perceptual reach into alien environments here on Earth, too. In 2007, European researchers led by J.L. Deneubourg described a novel experiment in which they developed autonomous robots that infiltrated and influenced a community of cockroaches. The relatively simple robots were able to sense the difference between light and dark environments and move to one or the other as the researchers wanted. The miniature machines didn’t look like cockroaches, but they did smell like them, because the scientists covered them with pheromones that were attractive to other cockroaches from the same clan.

The goal of the experiment was to better understand the insects’ social behavior. Generally, cockroaches prefer to cluster in dark environments with others of their kind. The preference for darkness makes sense—they’re less vulnerable to predators or disgusted humans when they’re hiding in the shadows. When the researchers instructed their pheromone-soaked machines to group together in the light, however, the other cockroaches followed. They chose the comfort of a group despite the danger of the light. 

JACK SNELLING

These robotic roaches bring me back to my first conversation with Roger Payne all those years ago, and his dreams of swimming alongside his majestic friends. What if we could build a robot that accomplished something similar to his imagined capsule? What if we could create a robotic fish that moved alongside marine creatures and mammals like a regular member of the aquatic neighborhood? That would give us a phenomenal window into undersea life.

Sneaking into and following aquatic communities to observe behaviors, swimming patterns, and creatures’ interactions with their habitats is difficult. Stationary observatories cannot follow fish. Humans can only stay underwater for so long. Remotely operated and autonomous underwater vehicles typically rely on propellers or jet-based propulsion systems, and it’s hard to go unnoticed when your robot is kicking up so much turbulence. We wanted to create something different—a robot that actually swam like a fish. This project took us many years, as we had to develop new artificial muscles, soft skin, novel ways of controlling the robot, and an entirely new method of propulsion. I’ve been diving for decades, and I have yet to see a fish with a propeller. Our robot, SoFi (pronounced like Sophie), moves by swinging its tail back and forth like a shark. A dorsal fin and twin fins on either side of its body allow it to dive, ascend, and move through the water smoothly, and we’ve already shown that SoFi can navigate around other aquatic life forms without disrupting their behavior.

SoFi is about the size of an average snapper and has taken some lovely tours in and around coral reef communities in the Pacific Ocean at depths of up to 18 meters. Human divers can venture deeper, of course, but the presence of a scuba-­diving human changes the behavior of the marine creatures. A few scientists remotely monitoring and occasionally steering SoFi cause no such disruption. By deploying one or several realistic robotic fish, scientists will be able to follow, record, monitor, and potentially interact with fish and marine mammals as if they were just members of the community.

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